Your search keyword '"Henrik Haak"' showing total 2 results

1. Photoelectron spectroscopy from a liquid flatjet.

Author

Stemer, Dominik, Buttersack, Tillmann, Haak, Henrik, Malerz, Sebastian, Schewe, Hanns Christian, Trinter, Florian, Mudryk, Karen, Pugini, Michele, Credidio, Bruno, Seidel, Robert, Hergenhahn, Uwe, Meijer, Gerard, Thürmer, Stephan, and Winter, Bernd

Subjects

PHOTOELECTRON spectroscopy, SODIUM iodide, LIQUIDS, AQUEOUS solutions, PHOTOEMISSION, ORGANIC solvents

Abstract

We demonstrate liquid-jet photoelectron spectroscopy from a flatjet formed by the impingement of two micron-sized cylindrical jets of different aqueous solutions. Flatjets provide flexible experimental templates enabling unique liquid-phase experiments that would not be possible using single cylindrical liquid jets. One such possibility is to generate two co-flowing liquid-jet sheets with a common interface in vacuum, with each surface facing the vacuum being representative of one of the solutions, allowing face-sensitive detection by photoelectron spectroscopy. The impingement of two cylindrical jets also enables the application of different bias potentials to each jet with the principal possibility to generate a potential gradient between the two solution phases. This is shown for the case of a flatjet composed of a sodium iodide aqueous solution and neat liquid water. The implications of asymmetric biasing for flatjet photoelectron spectroscopy are discussed. The first photoemission spectra for a sandwich-type flatjet comprised of a water layer encapsulated by two outer layers of an organic solvent (toluene) are also shown. [ABSTRACT FROM AUTHOR]

Published

2023

2. Quantum-state selection, alignment, and orientation of large molecules using static electric and laser fields.

Author

Filsinger, Frank, Küpper, Jochen, Meijer, Gerard, Holmegaard, Lotte, Nielsen, Jens H., Nevo, Iftach, Hansen, Jonas L., and Stapelfeldt, Henrik

Subjects

MOLECULES, MOLECULAR beams, ELECTRIC fields, IODOBENZENE, QUANTUM theory, CHEMISTRY, PHYSICS

Abstract

Supersonic beams of polar molecules are deflected using inhomogeneous electric fields. The quantum-state selectivity of the deflection is used to spatially separate molecules according to their quantum state. A detailed analysis of the deflection and the obtained quantum-state selection is presented. The rotational temperatures of the molecular beams are determined from the spatial beam profiles and are all approximately 1 K. Unprecedented degrees of laser-induced alignment (2 θ2D>=0.972) and orientation of iodobenzene molecules are demonstrated when the state-selected samples are used. Such state-selected and oriented molecules provide unique possibilities for many novel experiments in chemistry and physics. [ABSTRACT FROM AUTHOR]

Published

2009